Product Description
Introduction of enterprise:
HangZhou Jinlibo Trade Co., Ltd. Has introduced sophisticated equipment from overseas to develop and manufacture semi-trailer axles and related parts. Holding ISO9001: 2000 certification for our management system, we faithfully follow the stipulations of this standard so as to guarantee high product quality.
Characteristics:
1. Special heat-treat, low-alloy steel axle beam, it has the vitues of good synthetic performance, strong load ability and lower self weight.
2. High quality alloy solid inserted spindle, through wholy heat treatment, provide superior fatigue capability.
3. High performance premium non-asbestos brake linings, estend serbice life.
4. Easy for ABS installation.
5. Camshaft, matching with special seals, can ensure no entry of the grease into the brake drum, more safety.
6. New tight fit hub cap habe O rings, high property for sealing.
7. Grease lubricant is supplied by Mobil that lengthens the time of free maintenance.
8. Full range of stud fixing such as ISO, BSF and JAP, it can meet the requirements of various wheel rims.
Scope of our business
1. Axles (German type axle, EngliSh type axle, American type axle, Spoke axle, ZM axle, Agriculture axle, Half axle, Axle without brake)
2. Suspension (Bogie suspension, One point suspension, Rigid suspension, Spoke suspension, Machinery suspension)
3. Landing gear
4. Fifth wheel (2” 3.5”)
5. King pin (2” 3.5”)
6. Semi trailer
7. Other axles and related parts (Low bed axle, hub, rims, spring, drum…)
| AXLE TYPE | BRAKE SIZE | WHEEL FIXING | NO.xSIZE OF WHEEL STUD | WHEE.REG.DIA(DIM B) | DIM.D | BEARING | MIN WHEEL | BEAM SIZE | AXLE CAPCITY | SPRING SET INSTALLATIONS | WEIGHT |
| RNY1218J | 420×180 | JAP | 8xM20x285 | 221 | 718 | 33213 218248 | 20″ | ?150 | 13T | ≤450 | 350KG |
| RNY1222J | 420×220 | JAP | 8xM20x285 | 221 | 738 | 33213 218248 | 20″ | ?150 | 13T | ≤450 | 370KG |
| RNY1218I | 420×180 | ISO | 10xM22x335 | 281 | 710 | 33213 218248 | 20″ | ?150 | 13T | ≤450 | 350KG |
| RNY1222I | 420×220 | ISO | 10xM22x335 | 281 | 730 | 33213 218248 | 20″ | ?150 | 13T | ≤450 | 380KG |
| RNY118B | 420×180 | BSF | 10×7/8″x335 | 281 | 701 | 33213 218248 | 20″ | ?150 | 13T | ≤450 | 350KG |
| RNY1220I | 420×200 | ISO | 10xM22x335 | 281 | 715 | 33213 218248 | 20″ | ?150 | 13T | ≤450 | 370KG |
| RNY1622B | 420×220 | BSF | 10×7/8″x335 | 281 | 721 | 218248 220149 | 20″ | ?150 | 16T | ≤450 | 420KG |
| RNY1622I | 420×220 | ISO | 10xM22x335 | 281 | 721 | 218248 220149 | 20″ | ?150 | 16T | ≤450 | 420KG |
| RNY1822I | 420×220 | ISO | 10xM22x335 | 281 | 721 | 218248 220149 | 20″ | ?150 | 18T | ≤450 | 450KG |
| RNY12018I | 420×180 | ISO | 10xM22x335 | 281 | 710 | 33213 218248 | 20″ | ø127×18 | 12T | ≤450 | 350KG |
| RNY12018J | 420×180 | JAP | 8xM20x285 | 221 | 718 | 33213 218248 | 20″ | ø127×18 | 12T | ≤450 | 340KG |
| RNY12018B | 420×180 | BSF | 10×7/8″x335 | 281 | 701 | 33213 218248 | 20″ | ø127×18 | 12T | ≤450 | 350KG |
| RNY12571I | 420×220 | ISO | 10xM22x335 | 281 | 730 | 33213 218248 | 20″ | ø127×18 | 13T | ≤450 | 370KG |
| RNY16571I | 420×220 | ISO | 10xM22x335 | 281 | 721 | 218248 220149 | 20″ | ø127×18 | 16T | ≤450 | 430KG |
| RNY17571I | 420×220 | ISO | 10xM22x335 | 281 | 721 | 218248 220149 | 20″ | ø127×18 | 17.5T | ≤450 | 430KG |
| RNY1188I | 311×178 | ISO | 10xM22x335 | 176 | 690 | 33213 218248 | 15″ | ø127×18 | 10T | ≤390 | 260KG |
| RNY1518I | 311×178 | ISO | 10xM22x335 | 176 | 690 | 33213 218248 | 15″ | ø127×18 | 15T | ≤390 | 300KG |
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| Material: | 14oz T/C Canvas |
|---|---|
| Certification: | SGS, ISO/Ts16949, ISO |
| Position: | Rear |
| OEM: | No |
| Type: | Semi-Trailer |
| Condition: | New |
| Customization: |
Available
| Customized Request |
|---|
What is the role of axles in electric vehicles, and how do they differ from traditional axles?
Electric vehicles (EVs) have unique requirements when it comes to their drivetrain systems, including the axles. The role of axles in EVs is similar to traditional vehicles, but there are some key differences. Here’s a detailed explanation of the role of axles in electric vehicles and how they differ from traditional axles:
Role of Axles in Electric Vehicles:
The primary role of axles in electric vehicles is to transmit torque from the electric motor(s) to the wheels, enabling vehicle propulsion. The axles connect the motor(s) to the wheels and provide support for the weight of the vehicle. Axles are responsible for transferring the rotational force generated by the electric motor(s) to the wheels, allowing the vehicle to move forward or backward.
In electric vehicles, the axles are an integral part of the drivetrain system, which typically includes an electric motor(s), power electronics, and a battery pack. The axles play a crucial role in ensuring efficient power transfer and delivering the desired performance and handling characteristics of the vehicle.
Differences from Traditional Axles:
While the fundamental role of axles in electric vehicles is the same as in traditional vehicles, there are some notable differences due to the unique characteristics of electric propulsion systems:
1. Integration with Electric Motors: In electric vehicles, the axles are often integrated with the electric motors. This means that the motor(s) and axle assembly are combined into a single unit, commonly referred to as an “electric axle” or “e-axle.” This integration helps reduce the overall size and weight of the drivetrain system and simplifies installation in the vehicle.
2. High Torque Requirements: Electric motors generate high amounts of torque from the moment they start, providing instant acceleration. As a result, axles in electric vehicles need to handle higher torque loads compared to traditional axles. They are designed to withstand the torque output of the electric motor(s) and efficiently transmit it to the wheels.
3. Regenerative Braking: Electric vehicles often utilize regenerative braking, which converts the vehicle’s kinetic energy into electrical energy and stores it in the battery. The axles in electric vehicles may incorporate systems or components that enable regenerative braking, such as sensors, controllers, and electric brake actuators.
4. Space Optimization: Electric vehicles often have different packaging requirements compared to traditional internal combustion engine vehicles. The axles in electric vehicles are designed to accommodate the space constraints and specific layout of the vehicle, considering the placement of the battery pack, electric motor(s), and other components.
5. Weight Considerations: Electric vehicles strive to optimize weight distribution to enhance efficiency and handling. Axles in electric vehicles may be designed with lightweight materials or innovative construction techniques to minimize weight while maintaining structural integrity and durability.
It’s important to note that the specific design and characteristics of axles in electric vehicles can vary depending on the vehicle manufacturer, drivetrain configuration (e.g., front-wheel drive, rear-wheel drive, all-wheel drive), and other factors. Automotive manufacturers and suppliers continually innovate and develop new axle technologies to meet the evolving demands of electric vehicle propulsion systems.
Can you provide insights into the advancements in axle technology in recent years?
In recent years, there have been significant advancements in axle technology to enhance performance, efficiency, and safety in vehicles. Here are some insights into the key advancements:
- Lightweight Materials:
- Electronic Differential:
- Advanced Axle Bearings:
- Electric Axles:
- Active Suspension Integration:
- Improved Sealing and Lubrication:
- Autonomous Vehicle Integration:
One notable advancement is the use of lightweight materials in axle construction. Manufacturers have increasingly utilized materials such as aluminum alloys and high-strength steels to reduce the weight of axles without compromising strength and durability. Lighter axles contribute to improved fuel efficiency and overall vehicle performance.
Electronic differentials, also known as eDiffs, have gained popularity in recent years. They utilize sensors, actuators, and control algorithms to monitor and distribute torque between the wheels more efficiently. Electronic differentials enhance traction, stability, and handling by actively managing torque distribution, especially in vehicles equipped with advanced stability control systems.
Axle bearings have seen advancements in design and materials to reduce friction, improve efficiency, and enhance durability. For example, the use of roller bearings or tapered roller bearings has become more prevalent, offering reduced frictional losses and improved load-carrying capacity. Some manufacturers have also introduced sealed or maintenance-free bearings to minimize maintenance requirements.
With the rise of electric vehicles (EVs) and hybrid vehicles, electric axles have emerged as a significant technological advancement. Electric axles integrate electric motors, power electronics, and gear systems into the axle assembly. They eliminate the need for traditional drivetrain components, simplify vehicle packaging, and offer benefits such as instant torque, regenerative braking, and improved energy efficiency.
Advancements in axle technology have facilitated the integration of active suspension systems into axle designs. Active suspension systems use sensors, actuators, and control algorithms to adjust the suspension characteristics in real-time, providing improved ride comfort, handling, and stability. Axles with integrated active suspension components offer more precise control over vehicle dynamics.
Axles have seen advancements in sealing and lubrication technologies to enhance durability and minimize maintenance requirements. Improved sealing systems help prevent contamination and retain lubricants, reducing the risk of premature wear or damage. Enhanced lubrication systems with better heat dissipation and reduced frictional losses contribute to improved efficiency and longevity.
The development of autonomous vehicles has spurred advancements in axle technology. Axles are being designed to accommodate the integration of sensors, actuators, and communication systems necessary for autonomous driving. These advancements enable seamless integration with advanced driver-assistance systems (ADAS) and autonomous driving features, ensuring optimal performance and safety.
It’s important to note that the specific advancements in axle technology can vary across different vehicle manufacturers and models. Furthermore, ongoing research and development efforts continue to drive further innovations in axle design, materials, and functionalities.
For the most up-to-date and detailed information on axle technology advancements, it is advisable to consult automotive manufacturers, industry publications, and reputable sources specializing in automotive technology.
What is the primary function of an axle in a vehicle or machinery?
An axle plays a vital role in both vehicles and machinery, providing essential functions for their operation. The primary function of an axle is to transmit rotational motion and torque from an engine or power source to the wheels or other rotating components. Here are the key functions of an axle:
- Power Transmission:
- Support and Load Bearing:
- Wheel and Component Alignment:
- Suspension and Absorption of Shocks:
- Steering Control:
- Braking:
An axle serves as a mechanical link between the engine or power source and the wheels or driven components. It transfers rotational motion and torque generated by the engine to the wheels, enabling the vehicle or machinery to move. As the engine rotates the axle, the rotational force is transmitted to the wheels, propelling the vehicle forward or driving the machinery’s various components.
An axle provides structural support and load-bearing capability, especially in vehicles. It bears the weight of the vehicle or machinery and distributes it evenly across the wheels or supporting components. This load-bearing function ensures stability, balance, and proper weight distribution, contributing to safe and efficient operation.
The axle helps maintain proper alignment of the wheels or rotating components. It ensures that the wheels are parallel to each other and perpendicular to the ground, promoting stability and optimal tire contact with the road surface. In machinery, the axle aligns and supports the rotating components, ensuring their correct positioning and enabling smooth and efficient operation.
In vehicles, particularly those with independent suspension systems, the axle plays a role in the suspension system’s operation. It may incorporate features such as differential gears, CV joints, or other mechanisms that allow the wheels to move independently while maintaining power transfer. The axle also contributes to absorbing shocks and vibrations caused by road irregularities, enhancing ride comfort and vehicle handling.
In some vehicles, such as trucks or buses, the front axle also serves as a steering axle. It connects to the steering mechanism, allowing the driver to control the direction of the vehicle. By turning the axle, the driver can steer the wheels, enabling precise maneuverability and navigation.
An axle often integrates braking components, such as brake discs, calipers, or drums. These braking mechanisms are actuated when the driver applies the brakes, creating friction against the rotating axle or wheels and causing deceleration or stopping of the vehicle. The axle’s design can affect braking performance, ensuring effective and reliable stopping power.
Overall, the primary function of an axle in both vehicles and machinery is to transmit rotational motion, torque, and power from the engine or power source to the wheels or rotating components. Additionally, it provides support, load-bearing capability, alignment, suspension, steering control, and braking functions, depending on the specific application and design requirements.
editor by CX 2024-04-10